Systematic analysis of mitochondrial genes associated with hearing loss in the Japanese population: dHPLC reveals a new candidate mutation.

BACKGROUND: Variants of mitochondrial DNA (mtDNA) have been evaluated for their association with hearing loss. Although ethnic background affects the spectrum of mtDNA variants, systematic mutational analysis of mtDNA in Japanese patients with hearing loss has not been reported. METHODS: Using denaturing high-performance liquid chromatography combined with direct sequencing and cloning-sequencing, Japanese patients with prelingual (N = 54) or postlingual (N = 80) sensorineural hearing loss not having pathogenic mutations of m.1555A > G and m.3243A > G nor GJB2 were subjected to mutational analysis of mtDNA genes (12S rRNA, tRNALeu(UUR), tRNASer(UCN), tRNALys, tRNAHis, tRNASer(AGY), and tRNAGlu). RESULTS: We discovered 15 variants in 12S rRNA and one homoplasmic m.7501A > G variant in tRNASer(UCN); no variants were detected in the other genes. Two criteria, namely the low frequency in the controls and the high conservation among animals, selected the m.904C > T and the m.1105T > C variants in 12S rRNA as candidate pathogenic mutations. Alterations in the secondary structures of the two variant transcripts as well as that of m.7501A > G in tRNASer(UCN) were predicted. CONCLUSIONS: The m.904C > T variant was found to be a new candidate mutation associated with hearing loss. The m.1105T > C variant is unlikely to be pathogenic. The pathogenicity of the homoplasmic m.7501T > A variant awaits further study.

Maternal enrichment affects prenatal hippocampal proliferation and open-field behaviors in female offspring mice.

The maternal environment is thought to be important for fetal brain development. However, the effects of maternal environment are not fully understood. Here, we investigated whether enrichment of the maternal environment can influence prenatal brain development and postnatal behaviors in mice. An enriched environment is a housing condition with several objects such as a running wheel, tube and ladder, which are thought to increase sensory, cognitive and motor stimulation in rodents compared with standard housing conditions. First, we measured the number of BrdU-positive cells in the hippocampal dentate gyrus of fetuses from pregnant dams housed in an enriched environment. Our results revealed that maternal enrichment influences cell proliferation in the hippocampus of female, but not male, fetuses. Second, we used the open-field test to investigate postnatal behaviors in the offspring of dams housed in the enriched environment during pregnancy. We found that maternal enrichment significantly affects the locomotor activity and time spent in the center of the open-field in female, but not male, offspring. These results indicate that maternal enrichment influences prenatal brain development and postnatal behaviors in female offspring.

Maternal supply of BDNF to mouse fetal brain through the placenta.

Gastrointestinal peptides and hormones are known to penetrate through the utero-placental barrier and regulate fetal development. In the present study, we tested permeation of maternal brain-derived neurotrophic factor (BDNF) to fetuses, using BDNF-gene deficient mice and exogenous BDNF administration. At embryonic day 13.5 (E13.5)-14.5, BDNF protein concentrations in the fetal brain of BDNF homozygous null mutant (bdnf (-/-)) were comparable to the levels seen in wild-type fetuses. After E17.5, BDNF protein levels in bdnf (-/-) fetal brain were still detectable but its levels were significantly decreased below those in wild-type brain. When recombinant BDNF protein was injected into pregnant wild-type mice carrying E14.5 embryos, BDNF protein levels in fetal brain were elevated dose-dependently. These findings suggest that maternal BDNF reaches the fetal brain through utero-placental barrier and might contribute to its development.

Ghrelin alters postnatal endocrine secretion and behavior in mouse offspring.

Maternal bioactive substances, such as hormones and neuropeptides, are thought to be essential for fetal development. Recently, ghrelin, a gastrointestinal peptide, has been shown to pass through the rat placenta. The ghrelin receptor, growth hormone secretagogue receptor (GHS-R), has been shown to be expressed in the rat fetal central nervous system, and plasma ghrelin levels are related to birth weight in the rodent and human. In the present study, we report a role of maternal ghrelin in mouse fetal brain development. When ghrelin was administrated to pregnant mice, pups exhibited suppression of exploratory behavior in an open-field (OF) test. Control pups, however, remained for longer periods of time in the center area, correlating with exploratory behavior. Basal corticotropin-releasing hormone (CRH) plasma levels were greater in pups from ghrelin-treated dams, and did not change in response to acute restraint stress. Moreover, reduced growth hormone secretagogue receptor and neuropeptide Y mRNA expression was observed in the hypothalamus at postnatal day 3 and remained until 16 weeks of age. In addition, under physiological condition, increased maternal ghrelin plasma levels following repeated restraint stress to the dam had effect on the increase in fetal plasma acyl ghrelin levels. These results suggest that maternal ghrelin affect fetal plasma ghrelin levels and alters endocrine systems and behaviors of offspring.

Disrupted fat absorption attenuates obesity induced by a high-fat diet in Clock mutant mice.

The Clock gene is a core component of the circadian clock in mammals. We show here that serum levels of triglyceride and free fatty acid were significantly lower in circadian Clock mutant ICR than in wild-type control mice, whereas total cholesterol and glucose levels did not differ. Moreover, an increase in body weight induced by a high-fat diet was attenuated in homozygous Clock mutant mice. We also found that dietary fat absorption was extremely impaired in Clock mutant mice. Circadian expressions of cholecystokinin-A (CCK-A) receptor and lipase mRNAs were damped in the pancreas of Clock mutant mice. We therefore showed that a Clock mutation attenuates obesity induced by a high-fat diet in mice with an ICR background through impaired dietary fat absorption. Our results suggest that circadian clock molecules play an important role in lipid homeostasis in mammals.